EP0047561A1 - Method of determining the position of a mobile object - Google Patents

Method of determining the position of a mobile object Download PDF

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Publication number
EP0047561A1
EP0047561A1 EP81200984A EP81200984A EP0047561A1 EP 0047561 A1 EP0047561 A1 EP 0047561A1 EP 81200984 A EP81200984 A EP 81200984A EP 81200984 A EP81200984 A EP 81200984A EP 0047561 A1 EP0047561 A1 EP 0047561A1
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European Patent Office
Prior art keywords
location
mobile object
beats
time difference
radio
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EP81200984A
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German (de)
French (fr)
Inventor
Ole Snedkerud
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BBC Brown Boveri AG Switzerland
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BBC Brown Boveri AG Switzerland
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    • GPHYSICS
    • G01MEASURING; TESTING
    • G01SRADIO DIRECTION-FINDING; RADIO NAVIGATION; DETERMINING DISTANCE OR VELOCITY BY USE OF RADIO WAVES; LOCATING OR PRESENCE-DETECTING BY USE OF THE REFLECTION OR RERADIATION OF RADIO WAVES; ANALOGOUS ARRANGEMENTS USING OTHER WAVES
    • G01S1/00Beacons or beacon systems transmitting signals having a characteristic or characteristics capable of being detected by non-directional receivers and defining directions, positions, or position lines fixed relatively to the beacon transmitters; Receivers co-operating therewith
    • G01S1/02Beacons or beacon systems transmitting signals having a characteristic or characteristics capable of being detected by non-directional receivers and defining directions, positions, or position lines fixed relatively to the beacon transmitters; Receivers co-operating therewith using radio waves
    • G01S1/08Systems for determining direction or position line
    • G01S1/20Systems for determining direction or position line using a comparison of transit time of synchronised signals transmitted from non-directional antennas or antenna systems spaced apart, i.e. path-difference systems
    • G01S1/30Systems for determining direction or position line using a comparison of transit time of synchronised signals transmitted from non-directional antennas or antenna systems spaced apart, i.e. path-difference systems the synchronised signals being continuous waves or intermittent trains of continuous waves, the intermittency not being for the purpose of determining direction or position line and the transit times being compared by measuring the phase difference
    • G01S1/304Analogous systems in which a beat frequency, obtained by heterodyning the signals, is compared in phase with a reference signal obtained by heterodyning the signals in a fixed reference point and transmitted therefrom, e.g. LORAC (long range accuracy) or TORAN systems
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01SRADIO DIRECTION-FINDING; RADIO NAVIGATION; DETERMINING DISTANCE OR VELOCITY BY USE OF RADIO WAVES; LOCATING OR PRESENCE-DETECTING BY USE OF THE REFLECTION OR RERADIATION OF RADIO WAVES; ANALOGOUS ARRANGEMENTS USING OTHER WAVES
    • G01S5/00Position-fixing by co-ordinating two or more direction or position line determinations; Position-fixing by co-ordinating two or more distance determinations
    • G01S5/02Position-fixing by co-ordinating two or more direction or position line determinations; Position-fixing by co-ordinating two or more distance determinations using radio waves
    • G01S5/10Position of receiver fixed by co-ordinating a plurality of position lines defined by path-difference measurements, e.g. omega or decca systems

Definitions

  • the present invention relates to a method for determining the location of a mobile object by means of radio signals emitted by at least two fixed transmitting stations.
  • Radio location methods have so far been developed especially for sea and air vehicles and for location determination within very large areas.
  • the signals emitted by two and preferably three transmitting stations are received and evaluated.
  • a first common method (Loran)
  • synchronized pulses are transmitted and the time difference of the received pulses is measured
  • a second common method (Decca)
  • frequency and phase-synchronized continuous signals are transmitted, and the phase difference of the received signals is measured.
  • the required synchronization of the emitted signals means that the hyper loads are stationary and form stand lines that can be entered on a map.
  • the measured time or phase differences are then shown on a suitable map determines the base lines, where the intersection of two base lines indicates the current location of the recipient.
  • the present invention is therefore based on the object of providing a method for determining the current location of a mobile object which does not require a new transmitter chain, the measuring frequencies of which can be integrated into frequency bands which have already been used but are optimally suitable for the intended purpose, and with a comparatively low frequency technical effort allows a previously unattainable accuracy of location determination.
  • this object is achieved with a method which is characterized in that the signals directly or indirectly generate a field of electromagnetic beats generate whose in-phase sections move at a predetermined speed on confocal hyperbases from one to the other, each forming a focal point of the assigned hyperbola, and the time difference between the passage of a defined phase section of a beat at a reference location, the position of which relative to the two transmitting stations by one Reference hyperload is determined, as well as measured at the location of the mobile object and from this the hyperload intersecting this location is determined.
  • three fields of electromagnetic beats are generated by means of three transmitting stations.
  • the new method does not require its own transmitter network with an assigned frequency band, but can be carried out with signals that are modulated onto the carrier wave of existing radio transmitters without affecting the radio program.
  • signals When using carrier waves in the medium or long wave range, neither distortions nor reflections are to be expected even near the ground, which enables great accuracy in the measurement of the time difference and the determination of the location of the mobile object derived therefrom.
  • the signals do not have to be synchronized, which considerably simplifies and reduces the cost of implementing the method. With a suitable choice of the frequencies of the signals used, it is possible to generate a traveling speed of the beats, which enables the location of a mobile object to be determined with an accuracy of up to + 2 m.
  • the method is not only suitable for self-location, but enables by sending the location signals to a central receiver, the remote monitoring and control of a moving object.
  • Fig. 1 two transmitters 10, 11 are shown, which emit electromagnetic waves that spread in concentric circles around the respective transmitter. If the emitted waves are frequency and phase-synchronized, then they overlap to form a field of standing waves, the in-phase parts of which form a symmetrical array of confocal hyperbolas, for which the transmitters are the focal points. This phenomenon is practically used in the radio location method mentioned at the beginning with a hyperbola as a base line. If the emitted waves are neither frequency-synchronized nor phase-synchronized and the difference between the two frequencies is only a few Hertz, then the waves overlap to form beats, the zero crossing of which moves from one transmitter to the other on an infinite number of confocal hyperbolas.
  • f 1 and f 2 the frequencies of the two emitted waves are designated f 1 and f 2 .
  • the figure further shows a control station 13 and a hyperload 14 which runs through this control station (and around the transmitter 10 as the focal point) and which intersects the straight line 12 at point 15.
  • a mobile object which is briefly referred to below as mobile station 17, is shown.
  • a hyperload 18 runs through the mobile station and intersects the straight connecting line at point 19.
  • the hyperbole can be defined as the geometrical location of all points for which the difference in the distance from the two focal points (in the present view these are the two transmitters). is constant, the simple determination of the point 15 at which the hyperload 14 running through the location of the control station 13 intersects the connecting line 12. If in addition the frequencies of the waves emitted by the two transmitters are known and the time difference between the passage of the zero point of the beat through the location of the control station 13 and the location of a mobile station 17 is measured, then the relationship can be deduced calculate the distance of the point from the intersection 15 and thus determine the hyperload 18 running through the location of the mobile station.
  • a further auxiliary line that intersects the hyperload 18 in the location of the mobile station For this purpose, a second field of electromagnetic waves is used, which also forms beats and in the range of which the control station and the mobile station are located. For this second wave field, it is simply possible to use only one additional transmitter which interacts with one of the transmitters already described. This additional third transmitter is preferably selected such that its connecting line to the assigned transmitter intersects the connecting line between the first two transmitters at an obtuse angle. Then the hyperbores of the second also intersect Beat field at an obtuse angle with the hyper loads of the first beat field, which enables an optimal determination of the location of the mobile station.
  • FIG. 2 schematically shows a system with which the location of a mobile station can be determined using the above considerations.
  • the system includes three stationary radio transmitters 30, 31, 32 which, for example, transmit a radio program on the amplitude-modulated carrier frequencies F 30 , F 31 and F 32 , which are preferably in the medium or long wave range.
  • Each of said carrier waves having a or- tu n g s f re q uence f 300 f 31 f '32 frequency-modulated for the application of interest here.
  • the locating frequency is preferably in a range between 10 to 30 Hz in order not to noticeably impair the radio program.
  • the geographical distance between the transmitters can be very long as long as there is an area in which all three transmitters are well received.
  • the system also includes a stationary control station 35, which is installed in the reception area mentioned.
  • the control station contains a receiving device 36 with which the three radio transmitters can be received and the locating frequencies f '30 , f' 31 ' f' 32 can be demodulated.
  • the control station also contains a signal processing device 37, which converts the demodulated locating frequencies into predetermined harmonics or other locating auxiliary frequencies f ' k30' f ' k31 and f' k32 which can be distinguished from the locating frequencies .
  • the control station also contains an FM transmitter 38, the carrier wave F 38 of which is modulated with the three locating aid frequencies.
  • the reception area of the FM transmitter determines the area 21 (FIG. 1) in which a location can be determined.
  • the mobile station 40 requires two receiving devices 41, 42 with which the three radio transmitters or the FM transmitter can be received.
  • the receiving device 41 provided for the reception of the radio transmitters can be constructed in the same way as the corresponding receiving device 36 in the control station and, like this, delivers the three received locating frequencies f " 30 , f" 31r f "32 at separate outputs.
  • the other one for receiving the VHF transmitter 38 provided receiving device 42 contains a demodulator, at whose three outputs the locating aid frequencies f ' k30 , f ' k31 and f ' k32 appear.
  • This VHF receiving device is a device 43 for converting the locating aid frequencies back into those received by the control station Locating frequencies f ' 30' f '31 and f' 32 are connected downstream.
  • the outputs of the receiving device 41 and the device 43 are connected to assigned inputs of a signal processing device 44.
  • the accuracy of the location determination depends on the traveling speed of the beatings or the time interval between the passage of two successive and corresponding phase sections and, for example, the zero crossing of the beatings at a given location and on the accuracy of the determination of this time interval.
  • a beat frequency in the kilohertz range enables the location determination to be sufficiently accurate for the intended application, and its zero crossing can be measured with a reasonable amount of circuitry.
  • a computer 45 is connected downstream of the signal processing device 44.
  • the location frequencies f '30 ... and f " 30 ... received by the control station and the mobile station are specified in the computer by multiplication with n s constant factors in Messfre uenze q n n 1 f '30, n 2 f' 31 ..., and n 1 f "30, n 2 f" 31 ... transposed which lie in the preferred for evaluating frequency range.
  • the calculated transit times can be evaluated in different ways.
  • the runtimes are output by the computer and a map is used on which the connecting lines between the transmitters 30, 31 and the transmitters 30, 32 as well as assigned hyper loads are entered.
  • the two hyperbaric branches that intersect the control station (and only one branch 14 of which is shown in FIG. 2) form the reference hyperbaric branches and are preferably emphasized by their graphic representation.
  • Each of the other hyper-burdens is identified with a time stamp. This specifies the time span that the zero crossing of the beat formed by the assigned locating frequencies and traveling along the connecting line requires from the intersection of the connecting line with the reference hyperbalance to the intersection of the connecting line with the marked hyperload. An operator then sees from the intersection of the two hyper loads, their markings with the time calculated by the computer differences match, the current location of the mobile station.
  • the mobile station When using the system described to guide a vehicle, the mobile station must also be equipped with a transmitter 47, which forwards the calculated coordinates to the guide station. With such a system, however, it is also possible to transpose the locating and locating auxiliary signals received by the mobile station and to transmit them again unprocessed and to carry out the processing and evaluation in the leading station.
  • the reception area of the medium and long wave transmitters 30, 31, 32 is generally much larger than that of the VHF transmitter of the control station 35. This may result in the need to provide several control stations in the reception area of the medium or long wave transmitters and one for each control station Create a map with the assigned hyper loads. Then it must also be ensured that the original locating frequencies in neighboring control stations, the reception areas of which partially overlap, are converted into distinguishable locating auxiliary frequencies.
  • the electronic equipment in each control station is then advantageously supplemented by a memory 50, in which the data of all the parameters relating to the control station are stored, and by a modulator 51, which modulates this data onto the locating aid frequencies to be transmitted.
  • An additional demodulator 52 is then required in the mobile station received auxiliary positioning frequencies, the data of the parameters relating to the special control station are recovered and stored in a buffer memory 53, where they are called up by the computer.
  • the frequencies of the location signals are preferably in the range between 10 to 30 Hz.
  • the stereo pilot tone can simply be used as a location signal and an additional location signal can be dispensed with.
  • the measurement accuracy of the location determination that can be achieved with the new method is of course dependent on the constancy of the location frequencies and on the accuracy of the determination of the running time of the zero crossing of the beat through the location of the control and mobile station.
  • the phase position of a beat traveling at a known speed is evaluated in the new method, which is why the various processing steps must be carried out in such a way that the phase position of the original locating signals can also be recovered from the processed signals.
  • the location of an immobile mobile station can be determined with an accuracy of approximately 5 m.
  • a location error occurs because the mobile station continues to move within the time period required for the location determination. If the location is determined at a mobile station speed of 180 km / h , the error caused by locomotion is on average + 3 to +6 m, maximum + 6 to ⁇ 12 m.
  • the intersection point 19 of the hyperload 18 running through the mobile station lies with the connecting line 12 between the intersection point 15 and the transmitter 11.
  • On the connecting straight line there is another point, not shown, which lies between the intersection point 15 and the transmitter 10 and which also has the distance a from the intersection 15.
  • it can be determined from the phase difference of the location or measurement signals whether the distance a lies on the connecting line 12 between the intersection 15 and the transmitter 10 or the transmitter 11, which is why the location is unambiguous.

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  • Engineering & Computer Science (AREA)
  • Physics & Mathematics (AREA)
  • General Physics & Mathematics (AREA)
  • Radar, Positioning & Navigation (AREA)
  • Remote Sensing (AREA)
  • Power Engineering (AREA)
  • Computer Networks & Wireless Communication (AREA)
  • Position Fixing By Use Of Radio Waves (AREA)

Abstract

In the novel method, two beats are used for determining the location of an object (17), the drift velocity of which beats along an associated reference line (12, among others) can be calculated from the frequencies of the waves generating the beats and the location with the same phase angle of which beats can be calculated from the sources (10, 11, among others) of these waves. To determine the location, the delay times at predetermined phase angles of at least two beats are measured from a reference location (13) to the location of the object (17) and from this the reference lines are determined at the point of intersection of which the location of the object is positioned. <IMAGE>

Description

Die vorliegende Erfindung betrifft ein Verfahren zum Bestimmen des Ortes eines mobilen Objekts mittels von mindestens zwei ortsfesten Sendestationen ausgesandten funktechnischen Signalen.The present invention relates to a method for determining the location of a mobile object by means of radio signals emitted by at least two fixed transmitting stations.

Funkortungsverfahren sind bisher insbesondere für See- und Luftfahrzeuge und für die Standortbestimmung innerhalb sehr grosser Gebiete entwickelt worden. Bei diesen Verfahren werden die von zwei und vorzugsweise drei Sendestationen ausgesandten Signale empfangen und ausgewertet. Bei einem ersten gebräuchlichen Verfahren (Loran) werden synchronisierte Impulse ausgesandt und die Zeitdifferenz der empfangenen Impulse gemessen, bei einem zweiten gebräuchlichen Verfahren (Decca) werden frequenz- und phasensynchronisierte Dauersignale ausgesandt, und es wird die Phasendifferenz der empfangenen Signale gemessen. Für beide Verfahren gilt, dass die Orte, an denen die empfangenen Signale die gleiche Zeit- bzw. Phasendifferenz aufweisen, auf einem Hyperbelast liegen, für den einer der beiden Sender der Brennpunkt ist. Die geforderte Synchronisierung der ausgesandten Signale bewirkt, dass die Hyperbeläste ortsfest sind und Standlinien bilden, die auf einer Landkarte eingetragen werden können. Zur Ortsbestimmung werden dann auf einer geeigneten Karte die den gemessenen Zeit- bzw. Phasendifferenzen entsprechenden Standlinien bestimmt, wobei der Schnittpunkt zweier Standlinien den momentanen Standort des Empfängers angibt.Radio location methods have so far been developed especially for sea and air vehicles and for location determination within very large areas. In these methods, the signals emitted by two and preferably three transmitting stations are received and evaluated. In a first common method (Loran), synchronized pulses are transmitted and the time difference of the received pulses is measured, in a second common method (Decca), frequency and phase-synchronized continuous signals are transmitted, and the phase difference of the received signals is measured. It applies to both methods that the locations at which the received signals have the same time or phase difference lie on a hyperload for which one of the two transmitters is the focal point. The required synchronization of the emitted signals means that the hyper loads are stationary and form stand lines that can be entered on a map. To determine the location, the measured time or phase differences are then shown on a suitable map determines the base lines, where the intersection of two base lines indicates the current location of the recipient.

Inzwischen besteht auch die Notwendigkeit nach Verfahren zur Standortbestimmung innerhalb begrenzter Gebiete, beispielsweise längs der Küste, in grossen Häfen, zur Führung von Rettungsfahrzeugen, von Feuerwehr und Polizei oder für die Ueberwachung und Leitung des öffentlichen Verkehrs auf Vororts- und Ueberlandstrecken. Für solche Anwendungen sind die oben beschriebenen Verfahren nicht geeignet. Diese erfordern wegen der unumgänglichen Synchronisierung eine eigene Senderkette und sind darum rein materiell sehr aufwendig und teuer. Ausserdem sollte die Standortbestimmung wegen der Verzerrung von UKW-Signalen in Bodennähe nach Möglichkeit mit Frequenzen im Mittel- und Langwellenbereich durchgeführt werden, was ohne Störung durch bereits erstellte Rundfunksender praktisch nicht mehr möglich ist. Schliesslich beträgt die Genauigkeit der Standortbestimmung mit den genannten Verfahren bei vertretbarem technischen Aufwand bestenfalls + 300 m, was beispielsweise für die Führung eines Rettungshelikopters im Gebirge nicht ausreicht.In the meantime, there is also a need for procedures for determining the location within limited areas, for example along the coast, in large ports, for guiding emergency vehicles, the fire service and the police, or for monitoring and managing public transport on local and interurban routes. The methods described above are not suitable for such applications. Because of the inevitable synchronization, these require their own transmitter chain and are therefore, in terms of material, very complex and expensive. In addition, due to the distortion of VHF signals near the ground, the location should be determined with frequencies in the medium and long wave range, which is practically no longer possible without interference from previously created radio stations. Finally, the accuracy of the location determination using the above-mentioned methods is at best + 300 m with reasonable technical effort, which is not sufficient, for example, to guide a rescue helicopter in the mountains.

Der vorliegenden Erfindung liegt darum die Aufgabe zugrunde, ein Verfahren zum Bestimmen des momentanen Standorts eines mobilen Objekts zu schaffen, das keine neue Senderkette benötigt, dessen Messfrequenzen in bereits genutzte, aber für den vorgesehenen Zweck optimal geeignete Frequenzbänder integriert werden können und das mit vergleichsweise geringem technischen Aufwand eine bisher nicht erreichbare Genauigkeit der Standortbestimmung ermöglicht.The present invention is therefore based on the object of providing a method for determining the current location of a mobile object which does not require a new transmitter chain, the measuring frequencies of which can be integrated into frequency bands which have already been used but are optimally suitable for the intended purpose, and with a comparatively low frequency technical effort allows a previously unattainable accuracy of location determination.

Erfindungsgemäss wird diese Aufgabe mit einem Verfahren gelöst, das dadurch gekennzeichnet, ist, dass die Signale direkt oder indirekt ein Feld elektromagnetischer Schwebungen erzeugen, deren phasengleiche Abschnitte mit vorgegebener Geschwindigkeit auf konfokalen Hyperbelästen von der einen zur anderen, je einen Brennpunkt der zugeordneten Hyperbeln bildenden Sendestation wandern und die Zeitdifferenz zwischen dem Durchlauf eines definierten Phasenabschnitts einer Schwebung an einem Bezugsort, dessen Lage relativ zu den beiden Sendestationen durch einen Bezugshyperbelast bestimmt ist, sowie am Ort des mobilen Objekts gemessen und daraus der diesen Ort schneidende Hyperbelast bestimmt wird.According to the invention, this object is achieved with a method which is characterized in that the signals directly or indirectly generate a field of electromagnetic beats generate whose in-phase sections move at a predetermined speed on confocal hyperbases from one to the other, each forming a focal point of the assigned hyperbola, and the time difference between the passage of a defined phase section of a beat at a reference location, the position of which relative to the two transmitting stations by one Reference hyperload is determined, as well as measured at the location of the mobile object and from this the hyperload intersecting this location is determined.

Bei einer bevorzugten Ausführungsform des neuen Verfahrens werden mittels drei Sendestationen drei Felder elektromagnetischer Schwebungen erzeugt. Für die vorgesehene Anwendung genügt es, wenn zwei dieser Felder ausgewertet werden, wozu für jedes der zwei Felder die oben definierte Zeitdifferenz gemessen und daraus zwei Hyperbeläste bestimmt werden, deren Schnittpunkt dem Ort des mobilen Objekts entspricht.In a preferred embodiment of the new method, three fields of electromagnetic beats are generated by means of three transmitting stations. For the intended application, it is sufficient if two of these fields are evaluated, for which purpose the time difference defined above is measured for each of the two fields and two hyper loads are determined therefrom, the intersection of which corresponds to the location of the mobile object.

Das neue Verfahren benötigt kein eigenes Sendernetz mit einem zugeordneten Frequenzband, sondern kann mit Signalen durchgeführt werden, die auf die Trägerwelle bestehender Rundfunksender aufmoduliert werden, ohne das Rundfunkprogramm zu beeinträchtigen. Bei der Verwendung von Trägerwellen im Mittel- oder Langwellenbereich sind auch in Bodennähe weder Verzerrungen noch Reflexionen zu erwarten, was eine grosse Genauigkeit bei der Messung der Zeitdifferenz und der daraus abgeleiteten Bestimmung des Standorts des mobilen Objekts ermöglicht. Die Signale müssen nicht synchronisiert sein, was die Anlage zur Ausführung des Verfahrens wesentlich vereinfacht und verbilligt. Bei geeigneter Wahl der Frequenzen der verwendeten Signale ist es möglich, eine Wandergeschwindigkeit der Schwebungen zu erzeugen, die die Bestimmung des Standorts eines mobilen Objekts mit einer Genauigkeit von bis zu + 2 m ermöglicht. Das Verfahren ist nicht nur für die Selbstortung geeignet, sondern ermöglicht durch Aussenden der Ortungssignale an einen zentralen Empfänger auch die Fernüberwachung und -leitung eines beweglichen Objekts.The new method does not require its own transmitter network with an assigned frequency band, but can be carried out with signals that are modulated onto the carrier wave of existing radio transmitters without affecting the radio program. When using carrier waves in the medium or long wave range, neither distortions nor reflections are to be expected even near the ground, which enables great accuracy in the measurement of the time difference and the determination of the location of the mobile object derived therefrom. The signals do not have to be synchronized, which considerably simplifies and reduces the cost of implementing the method. With a suitable choice of the frequencies of the signals used, it is possible to generate a traveling speed of the beats, which enables the location of a mobile object to be determined with an accuracy of up to + 2 m. The method is not only suitable for self-location, but enables by sending the location signals to a central receiver, the remote monitoring and control of a moving object.

Nachfolgend werden ein vereinfachtes Beispiel des neuen Verfahrens und eine zu dessen Ausführung geeignete Anlage mit Hilfe der Figuren beschrieben. Es zeigen:

  • Fig. 1 die schematische Darstellung einer zwischen zwei Sendern wandernden Schwebung sowie der Bestimmung der Entfernung zwischen zwei Orten aus der Wanderzeit der Schwebung und
  • Fig. 2 das Schema einer Anlage zur Ausführung des Verfahrens.
A simplified example of the new method and a system suitable for carrying it out are described below with the aid of the figures. Show it:
  • Fig. 1 is a schematic representation of a beat traveling between two transmitters and the determination of the distance between two locations from the travel time of the beat and
  • Fig. 2 shows the diagram of a plant for performing the method.

In Fig. 1 sind zwei Sender 10, 11 gezeigt, die elektromagnetische Wellen aussenden, die sich auf konzentrischen Kreisen um den jeweiligen Sender ausbreiten. Wenn die ausgesandten Wellen frequenz- und phasensynchron sind, dann überlagern sie sich zu einem Feld stehender Wellen, deren phasengleiche Teile eine symmetrische Schar konfokaler Hyperbeln bilden, für die die Sender die Brennpunkte sind. Diese Erscheinung wird bei dem eingangs erwähnten Funkortungsverfahren mit einer Hyperbel als Standlinie praktisch genutzt. Sind die ausgesandten Wellen weder frequenz- noch phasensynchronisiert und beträgt der Unterschied zwischen den beiden Frequenzen nur wenige Hertz, dann überlagern sich die Wellen zu Schwebungen, deren Nulldurchgang auf einer unendlichen Anzahl konfokaler Hyperbeln von dem einen Sender zum anderen wandern. Wenn die Frequenzen der beiden ausgesandten Wellen mit f1 und f2 bezeichnet werden, dann gilt für die Frequenz der Schwebung die bekannte Gleichung: f s = f l - f 2 und für die Wandergeschwindigkeit des Nulldurchgangs der Schwebung längs der Verbindungsgeraden 12 zwischen den beiden Sendern, die der Hauptachse der Hyperbel entspricht, die ebenfalls bekannte Beziehung

Figure imgb0001
worin c für die Ausbreitungsgeschwindigkeit der elektromagnetischen Wellen steht, die bekanntlich gleich der Lichtgeschwindigkeit ist.In Fig. 1, two transmitters 10, 11 are shown, which emit electromagnetic waves that spread in concentric circles around the respective transmitter. If the emitted waves are frequency and phase-synchronized, then they overlap to form a field of standing waves, the in-phase parts of which form a symmetrical array of confocal hyperbolas, for which the transmitters are the focal points. This phenomenon is practically used in the radio location method mentioned at the beginning with a hyperbola as a base line. If the emitted waves are neither frequency-synchronized nor phase-synchronized and the difference between the two frequencies is only a few Hertz, then the waves overlap to form beats, the zero crossing of which moves from one transmitter to the other on an infinite number of confocal hyperbolas. If the frequencies of the two emitted waves are designated f 1 and f 2 , then the known equation applies to the frequency of the beat: f s = f l - f 2 and for the traveling speed of zero passage of the beat along the connecting line 12 between the two transmitters, which corresponds to the main axis of the hyperbola, the relationship also known
Figure imgb0001
 where c stands for the speed of propagation of the electromagnetic waves, which is known to be equal to the speed of light.

Die Figur zeigt weiter eine Kontrollstation 13, sowie einen durch diese Kontrollstation (und um den Sender 10 als Brennpunkt) verlaufenden Hyperbelast 14, der die Verbindungsgerade 12 im Punkt 15 schneidet. Ausserdem ist ein mobiles Objekt, das im folgenden kurz als Mobilstation 17 bezeichnet wird, gezeigt. Durch die Mobilstation verläuft ein Hyperbelast 18, der die Verbindungsgerade im Punkt 19 schneidet.The figure further shows a control station 13 and a hyperload 14 which runs through this control station (and around the transmitter 10 as the focal point) and which intersects the straight line 12 at point 15. In addition, a mobile object, which is briefly referred to below as mobile station 17, is shown. A hyperload 18 runs through the mobile station and intersects the straight connecting line at point 19.

Es versteht sich, dass alle von der Verbindungsgeraden 12 beabstandeten und auf einem Hyperbelast liegenden phasengleichen Punkte einer von dem einen Sender zum anderen wandernden Schwebung Bahnen durchlaufen, die länger sind als die Verbindungsgerade, weshalb die in der Fortbewegungsrichtung gemessene Bahngeschwindigkeit jedes Punktes mit zunehmendem Abstand von der Verbindungsgeraden grösser wird. Das hat zur Folge, dass die Zeitdifferenz Δτ13, l7 zwischen dem Zeitpunkt τ13, an dem der Nulldurchgang einer Schwebung durch den Ort der Kontrollstation 13 wandert, und dem Zeitpunkt τ17, an dem der gleiche Nulldurchgang durch den Ort der Mobilstation 17 wandert, gleich der Zeitdifferenz Δτ15, 19 ist, innert der der gleiche Nulldurchgang der Schwebung längs der Verbindungsgeraden 12 vom Schnittpunkt 15 zum Schnittpunkt 19 wandert.It is understood that all the in-phase points spaced from the connecting line 12 and lying on a hyperload of a beat traveling from one transmitter to the other pass through paths which are longer than the connecting line, which is why the path speed of each point measured in the direction of travel increases with increasing distance from the connecting line becomes larger. As a result, the time difference Δτ 13 , l7 between the time τ 13 at which the zero crossing of a beat moves through the location of the control station 13 and the time τ 17 at which the same zero crossing moves through the location of the mobile station 17 , is equal to the time difference Δτ 15 , 19 , within which the same zero crossing of the beat moves along the connecting straight line 12 from the intersection 15 to the intersection 19.

Wenn der Ort der beiden Sender 10, 11 und der der Kontrollstation 13 bekannt sind, ermöglicht die Definition der Hyperbel als der geometrische Ort aller Punkte, für die die Differenz des Abstands von den beiden Brennpunkten (das sind bei der vorliegenden Betrachtung die beiden Sender) konstant ist, die einfache Bestimmung des Punktes 15, in dem der durch den Ort der Kontrollstation 13 verlaufende Hyperbelast 14 die Verbindungsgerade 12 schneidet. Wenn zusätzlich die Frequenzen der von den beiden Sendern ausgesandten Wellen bekannt sind und die Zeitdifferenz zwischen dem Durchgang des Nullpunkts der Schwebung durch den Ort der Kontrollstation 13 und den Ort einer Mobilstation 17 gemessen wird, dann lässt-sich aus der Beziehung

Figure imgb0002
der Abstand des Punktes vom Schnittpunkt 15 errechnen und damit der durch den Ort der Mobilstation verlaufende Hyperbelast 18 bestimmen.If the location of the two transmitters 10, 11 and that of the control station 13 are known, the hyperbole can be defined as the geometrical location of all points for which the difference in the distance from the two focal points (in the present view these are the two transmitters). is constant, the simple determination of the point 15 at which the hyperload 14 running through the location of the control station 13 intersects the connecting line 12. If in addition the frequencies of the waves emitted by the two transmitters are known and the time difference between the passage of the zero point of the beat through the location of the control station 13 and the location of a mobile station 17 is measured, then the relationship can be deduced
Figure imgb0002
 calculate the distance of the point from the intersection 15 and thus determine the hyperload 18 running through the location of the mobile station.

Für die Bestimmung des Orts der Mobilstation auf dem Hyperbelast 18 ist dann das Errechnen einer weiteren Hilfslinie erforderlich, die den Hyperbelast 18 im Ort der Mobilstation schneidet. Dazu wird ein zweites Feld elektromagnetischer Wellen verwendet, das ebenfalls Schwebungen bildet und in dessen Ausbreitungsbereich die Kontrollstation und die Mobilstation liegen. Einfacherweise kann für dieses zweite Wellenfeld nur ein zusätzlicher Sender verwendet werden, der mit einem der bereits beschriebenen Sender zusammenwirkt. Dieser zusätzliche dritte Sender wird vorzugsweise so gewählt, dass seine Verbindungsgerade zu dem zugeordneten Sender die Verbindungsgerade zwischen den beiden ersten Sendern in einem möglichst stumpfen Winkel schneidet. Dann schneiden sich auch die Hyperbeläste des zweiten Schwebungsfelds in einem stumpfen Winkel mit den Hyperbelästen des ersten Schwebungsfelds, was eine optimale Bestimmung des Orts der Mobilstation ermöglicht.To determine the location of the mobile station on the hyperload 18, it is then necessary to calculate a further auxiliary line that intersects the hyperload 18 in the location of the mobile station. For this purpose, a second field of electromagnetic waves is used, which also forms beats and in the range of which the control station and the mobile station are located. For this second wave field, it is simply possible to use only one additional transmitter which interacts with one of the transmitters already described. This additional third transmitter is preferably selected such that its connecting line to the assigned transmitter intersects the connecting line between the first two transmitters at an obtuse angle. Then the hyperbores of the second also intersect Beat field at an obtuse angle with the hyper loads of the first beat field, which enables an optimal determination of the location of the mobile station.

In Fig. 2 ist schematisch eine Anlage gezeigt, mit der unter Anwendung der obigen Ueberlegungen der Ort einer Mobilstation festgestellt werden kann. Zur Anlage gehören drei stationäre Rundfunksender 30, 31, 32, die auf den vorzugsweise im Mittel- oder Langwellenbereich liegenden, amplitudenmodulierten Trägerfrequenzen F30, F31 bzw. F32 beispielsweise ein Hörfunkprogramm senden. Für die hier interessierende Anwendung wird jede dieser Trägerwellen mit einer Or- tungsfrequenz f300 f31' f32 frequenzmoduliert. Die Ortungsfrequenz liegt vorzugsweise in einem Bereich zwischen 10 bis 30 Hz, um das Hörfunkprogramm nicht merklich zu beeinträchtigen. Der geografische Abstand zwischen den Sendern kann sehr gross sein, solange es ein Gebiet gibt, in dem alle drei Sender gut empfangen werden.FIG. 2 schematically shows a system with which the location of a mobile station can be determined using the above considerations. The system includes three stationary radio transmitters 30, 31, 32 which, for example, transmit a radio program on the amplitude-modulated carrier frequencies F 30 , F 31 and F 32 , which are preferably in the medium or long wave range. Each of said carrier waves having a or- tu n g s f re q uence f 300 f 31 f '32 frequency-modulated for the application of interest here. The locating frequency is preferably in a range between 10 to 30 Hz in order not to noticeably impair the radio program. The geographical distance between the transmitters can be very long as long as there is an area in which all three transmitters are well received.

Zur Anlage gehört weiter eine ortsfeste Kontrollstation 35, die in dem genannten Empfangsgebiet installiert ist. Die Kontrollstation enthält eine Empfangseinrichtung 36, mit der die drei Rundfunksender empfangen und die Ortungsfrequenzen f'30, f'31' f'32 demoduliert werden können. Weiter enthält die Kontrollstation eine Signalaufbereitungseinrichtung 37, die die demodulierten Ortungsfrequenzen in vorgegebene Harmonische oder andere von den Ortungsfrequenzen unterscheidbare Ortungshilfsfrequenzen f'k30' f'k31 und f'k32 wandelt. Schliesslich enthält die Kontrollstation noch einen UKW-Sender 38, dessen Trägerwelle F38 mit den drei Ortungshilfsfrequenzen moduliert wird.The system also includes a stationary control station 35, which is installed in the reception area mentioned. The control station contains a receiving device 36 with which the three radio transmitters can be received and the locating frequencies f '30 , f' 31 ' f' 32 can be demodulated. The control station also contains a signal processing device 37, which converts the demodulated locating frequencies into predetermined harmonics or other locating auxiliary frequencies f 'k30' f ' k31 and f' k32 which can be distinguished from the locating frequencies . Finally, the control station also contains an FM transmitter 38, the carrier wave F 38 of which is modulated with the three locating aid frequencies.

Das Empfangsgebiet des UKW-Senders bestimmt das Gebiet 21 (Fig. 1), in dem eine Ortsbestimmung möglich ist.The reception area of the FM transmitter determines the area 21 (FIG. 1) in which a location can be determined.

Die Mobilstation 40 benötigt zwei Empfangseinrichtungen 41, 42, mit denen die drei Rundfunksender bzw. der UKW-Sender empfangen werden können. Die eine für den Empfang der Rundfunksender vorgesehene Empfangseinrichtung 41 kann gleichartig aufgebaut sein wie die entsprechende Empfangseinrichtung 36 in der Kontrollstation und liefert wie diese an getrennten Ausgängen die drei empfangenen Ortungsfrequenzen f"30, f"31r f"32. Die andere für den Empfang des UKW-Senders 38 vorgesehene Empfangseinrichtung 42 enthält einen Demodulator, an dessen drei Ausgängen die Ortungshilfsfre- quenzen f'k30, f'k31 und f'k32 erscheinen. Dieser UKW-Empfangseinrichtung ist ein Gerät 43 zum Rückwandeln der Ortungshilfsfrequenzen in die von der Kontrollstation empfangenen Ortungsfrequenzen f'30' f'31 und f'32 nachgeschaltet. Die Ausgänge der Empfangseinrichtung 41 und des Geräts 43 sind mit zugeordneten Eingängen einer Signalverarbeitungseinrichtung 44 verbunden.The mobile station 40 requires two receiving devices 41, 42 with which the three radio transmitters or the FM transmitter can be received. The receiving device 41 provided for the reception of the radio transmitters can be constructed in the same way as the corresponding receiving device 36 in the control station and, like this, delivers the three received locating frequencies f " 30 , f" 31r f "32 at separate outputs. The other one for receiving the VHF transmitter 38 provided receiving device 42 contains a demodulator, at whose three outputs the locating aid frequencies f ' k30 , f ' k31 and f ' k32 appear. This VHF receiving device is a device 43 for converting the locating aid frequencies back into those received by the control station Locating frequencies f '30' f '31 and f' 32 are connected downstream. The outputs of the receiving device 41 and the device 43 are connected to assigned inputs of a signal processing device 44.

Die Genauigkeit der Ortsbestimmung ist von der Wandergeschwindigkeit der Schwebungen bzw. dem zeitlichen Abstand zwischen dem Durchlauf zweier aufeinanderfolgender und einander entsprechender Phasenabschnitte und beispielsweise des Nulldurchgangs der Schwebung an einem gegebenen Ort sowie von der Genauigkeit der Bestimmung dieses zeitlichen Abstands abhängig. Wie gezeigt werden konnte, ermöglicht eine Schwebungsfrequenz im Kilohertzbereich eine für die vorgesehene Anwendung hinreichende Genauigkeit der Ortsbestimmung, und ihr Nulldurchgang kann mit vertretbarem schaltungstechnischen Aufwand gemessen werden.The accuracy of the location determination depends on the traveling speed of the beatings or the time interval between the passage of two successive and corresponding phase sections and, for example, the zero crossing of the beatings at a given location and on the accuracy of the determination of this time interval. As could be shown, a beat frequency in the kilohertz range enables the location determination to be sufficiently accurate for the intended application, and its zero crossing can be measured with a reasonable amount of circuitry.

Der Signalverarbeitungseinrichtung 44 ist ein Computer 45 nachgeschaltet. Im Computer werden die von der Kontrollstation und der Mobilstation empfangenen Ortungsfrequenzen f'30 ... bzw. f"30 ... durch Multiplikation mit vorgegebenen konstanten Faktoren in Messfrequenzen n1 f'30, n2f'31 ... bzw. n1 f"30, n2f"31 ... transponiert, die in dem zur Auswertung bevorzugten Frequenzbereich liegen. Weiter werden in Computer aus den transponierten Ortungsfrequenzen Differenzen gebildet: nlf'30 - n2f'30 = Δf'30, 31 ; n1f'30 - n3f'32 =Δf'30, 32 sowie n1f"30 - n2f"31 = Δf"30, 31; n1f"30 - n3f"32 =Δf"30, 32' die die Frequenzen der von den Ortungsfrequenzen 30, 31 und 30, 32 am Ort der Kontrollstation bzw. der Mobilstation erzeugten Schwebungen angeben. Aus diesen transponierten Ortungsfrequenzdifferenzen errechnet der Computer schliesslich den Momentanwert der Phasenlage der einander entsprechenden Schwebungen am Ort der Kontroll- und der Mobilstation und daraus die Laufzeit der Nullpunkte der diesen Differenzen entsprechenden Schwebungen zwischen den beiden Orten.A computer 45 is connected downstream of the signal processing device 44. The location frequencies f '30 ... and f " 30 ... received by the control station and the mobile station are specified in the computer by multiplication with n s constant factors in Messfre uenze q n n 1 f '30, n 2 f' 31 ..., and n 1 f "30, n 2 f" 31 ... transposed which lie in the preferred for evaluating frequency range. In addition, differences are formed in the computer from the transposed location frequencies: n l f '30 - n 2 f' 30 = Δf '30 , 31 ; n 1 f '30 - n 3 f' 32 = Δf '30 , 32 and n 1 f " 30 - n 2 f" 31 = Δf " 30 , 31 ; n 1 f" 30 - n 3 f " 32 = Δf" 30 , 32 'which indicate the frequencies of the beats generated by the locating frequencies 30, 31 and 30, 32 at the location of the control station or the mobile station. From these transposed location frequency differences, the computer finally calculates the instantaneous value of the phase position of the corresponding beats at the location of the control and mobile stations and from this the running time of the zero points of the beats corresponding to these differences between the two locations.

Die Auswertung der errechneten Laufzeiten kann auf verschiedene Arten erfolgen. Im einfachsten Fall werden die Laufzeiten vom Computer ausgegeben, und es wird eine Landkarte verwendet, auf der die Verbindungslinien zwischen den Sendern 30, 31 und den Sendern 30, 32 sowie zugeordnete Hyperbeläste eingetragen sind. Die beiden Hyperbeläste, die die Kontrollstation schneiden(und von denen in Fig. 2 nur der eine Ast 14 gezeigt ist), bilden die Bezugshyperbeläste und sind vorzugsweise durch ihre grafische Darstellung hervorgehoben. Jeder der anderen Hyperbeläste ist mit einer Zeitmarke identifiziert. Diese gibt die Zeitspanne an, die der Nulldurchgang der von den zugeordneten Ortungsfrequenzen gebildeten und längs der Verbindungslinie wandernden Schwebung vom Schnittpunkt der Verbindungslinie mit dem Bezugshyperbalast bis zum Schnittpunkt der Verbindungslinie mit dem markierten Hyperbelast benötigt. Eine Bedienungsperson sieht dann aus dem Schnittpunkt der beiden Hyperbeläste, deren Markierungen mit den vom Computer errechneten Zeitdifferenzen übereinstimmen, den momentanen Standort der Mobilstation.The calculated transit times can be evaluated in different ways. In the simplest case, the runtimes are output by the computer and a map is used on which the connecting lines between the transmitters 30, 31 and the transmitters 30, 32 as well as assigned hyper loads are entered. The two hyperbaric branches that intersect the control station (and only one branch 14 of which is shown in FIG. 2) form the reference hyperbaric branches and are preferably emphasized by their graphic representation. Each of the other hyper-burdens is identified with a time stamp. This specifies the time span that the zero crossing of the beat formed by the assigned locating frequencies and traveling along the connecting line requires from the intersection of the connecting line with the reference hyperbalance to the intersection of the connecting line with the marked hyperload. An operator then sees from the intersection of the two hyper loads, their markings with the time calculated by the computer differences match, the current location of the mobile station.

Es ist natürlich auch möglich, einen Computer zu verwenden, der anstelle der Zeitdifferenzen die Koordinaten der Mobilstation entweder absolut oder relativ zu einem anderen Ort, beispielsweise zur Kontrollstation, errechnet und ausgibt.It is of course also possible to use a computer which, instead of the time differences, calculates and outputs the coordinates of the mobile station either absolutely or relative to another location, for example to the control station.

Bei der Verwendung der beschriebenen Anlage zur Führung eines Fahrzeugs muss die Mobilstation noch mit einem Sender 47 bestückt werden, der die errechneten Koordinaten an die Führungsstation weitergibt. Bei einer solchen Anlage ist es aber auch möglich, die von der Mobilstation empfangenen Ortungs- und Ortungshilfssignale zu transponieren und unverarbeitet wieder auszusenden und die Verarbeitung und Auswertung in der Führungsstation auszuführen.When using the system described to guide a vehicle, the mobile station must also be equipped with a transmitter 47, which forwards the calculated coordinates to the guide station. With such a system, however, it is also possible to transpose the locating and locating auxiliary signals received by the mobile station and to transmit them again unprocessed and to carry out the processing and evaluation in the leading station.

Das Empfangsgebiet der Mittel- und Langwellensender 30, 31, 32 ist im allgemeinen sehr viel grösser als das des UKW-Senders der Kontrollstation 35. Daraus kann sich die Notwendigkeit ergeben, im Empfangsgebiet der Mittel- oder Langwellensender mehrere Kontrollstationen vorzusehen und für jede Kontrollstation eine Karte mit den zugeordneten Hyperbelästen zu erstellen. Dann ist auch darauf zu achten, dass die ursprünglichen Ortungsfrequenzen in benachbarten Kontrollstationen, deren Empfangsbereiche sich teilweise überlagern, in unterscheidbare Ortungshilfsfrequenzen gewandelt werden. Vorteilhafterweise wird dann die elektronische Ausrüstung in jeder Kontrollstation durch einen Speicher 50 ergänzt, in dem die Daten aller die Kontrollstation betreffenden Parameter gespeichert sind, sowie durch einen Modulator 51, der diese Daten auf die auszusendenden Ortungshilfsfrequenzen aufmoduliert. In der Mobilstation ist dann ein zusätzlicher Demodulator 52 erforderlich, der aus den empfangenen Ortungshilfsfrequenzen die Daten der die spezielle Kontrollstation betreffenden Parameter zurückgewinnt und in einen Zwischenspeicher 53 einspeichert, wo sie vom Computer abgerufen werden.The reception area of the medium and long wave transmitters 30, 31, 32 is generally much larger than that of the VHF transmitter of the control station 35. This may result in the need to provide several control stations in the reception area of the medium or long wave transmitters and one for each control station Create a map with the assigned hyper loads. Then it must also be ensured that the original locating frequencies in neighboring control stations, the reception areas of which partially overlap, are converted into distinguishable locating auxiliary frequencies. The electronic equipment in each control station is then advantageously supplemented by a memory 50, in which the data of all the parameters relating to the control station are stored, and by a modulator 51, which modulates this data onto the locating aid frequencies to be transmitted. An additional demodulator 52 is then required in the mobile station received auxiliary positioning frequencies, the data of the parameters relating to the special control station are recovered and stored in a buffer memory 53, where they are called up by the computer.

Bei der oben beschriebenen Anlage erstrecken sich zwischen den drei Mittel- oder Langwellensendern drei Verbindungslinien, und es gibt längs jeder Verbindungslinie eine Schar Hyperbeläste. Für eine Ortsbestimmung sind jedoch nur zwei Scharen Hyperbeläste erforderlich, und die Auswertung der dritten Schar führt zu einer Ueberbestimmung.In the system described above, three connecting lines extend between the three medium or long-wave transmitters, and there is a bevy of hyperbores along each connecting line. For a location determination, however, only two sets of hyper loads are required, and the evaluation of the third set leads to an overestimation.

Wie bereits oben erwähnt wurde, liegen die Frequenzen der Ortungssignale vorzugsweise im Bereich zwischen 10 bis 30 Hz.As already mentioned above, the frequencies of the location signals are preferably in the range between 10 to 30 Hz.

Wenn einer der drei Rundfunksender ein Stereoprogramm aussendet, dann kann einfacherweise der Stereopilotton als Ortungssignal verwendet und auf ein zusätzliches Ortungssignal verzichtet werden. Das gleiche gilt für einen Zeit-Frequenznormal-Sender.If one of the three radio transmitters broadcasts a stereo program, then the stereo pilot tone can simply be used as a location signal and an additional location signal can be dispensed with. The same applies to a time-frequency standard transmitter.

Die mit dem neuen Verfahren erreichbare Messgenauigkeit der Ortsbestimmung ist natürlich von der Konstanz der Ortungsfrequenzen sowie von der Genauigkeit der Bestimmung der Laufzeit des Nulldurchgangs der Schwebung durch den Ort der Kontroll- und der Mobilstation abhängig. Dazu sei nochmals darauf hingewiesen, dass bei dem neuen Verfahren die Phasenlage einer mit bekannter Geschwindigkeit wandernden Schwebung ausgewertet wird, weshalb die verschiedenen Verarbeitungsschritte so auszuführen sind, dass auch aus den verarbeiteten Signalen die Phasenlage der ursprünglichen Ortungssignale zurückgewonnen werden kann.The measurement accuracy of the location determination that can be achieved with the new method is of course dependent on the constancy of the location frequencies and on the accuracy of the determination of the running time of the zero crossing of the beat through the location of the control and mobile station. In this regard, it should be pointed out again that the phase position of a beat traveling at a known speed is evaluated in the new method, which is why the various processing steps must be carried out in such a way that the phase position of the original locating signals can also be recovered from the processed signals.

Es konnte gezeigt werden, dass bei geeigneter Wahl der Messfrequenzen entsprechend einer Wandergeschwindigkeit des Nullpunkts der Schwebung von etwa 40 km/s und bei einer Messgenauigkeit des Nulldurchgangs von etwa 0,1 ms der Ort einer unbewegten Mobilstation mit einer Genauigkeit von etwa 5 m bestimmt werden kann.It could be shown that with a suitable choice of the measuring frequencies according to a walking speed of the Zero point of the beat of approximately 40 km / s and with a measuring accuracy of the zero crossing of approximately 0.1 ms, the location of an immobile mobile station can be determined with an accuracy of approximately 5 m.

Bei einer bewegten Mobilstation tritt ein Ortungsfehler auf, weil sich die Mobilstation innert der zur Ortsbestimmung erforderlichen Zeitspanne weiterbewegt. Wird die Ortsbestimmung bei einer Geschwindigkeit der Mobilstation von 180 km/ h durchgeführt, dann beträgt der durch die Fortbewegung bedingte Fehler im Mittel +3 bis +6 m, maximal + 6 bis ±12 m.In the case of a moving mobile station, a location error occurs because the mobile station continues to move within the time period required for the location determination. If the location is determined at a mobile station speed of 180 km / h , the error caused by locomotion is on average + 3 to +6 m, maximum + 6 to ± 12 m.

In allen obigen Betrachtungen ist die Ausbreitungsgeschwindigkeit der elektromagnetischen Wellen und insbesondere die Uebertragungszeit der Ortungsfrequenzen von der Kontrollzur Mobilstation nicht berücksichtigt. Mit entsprechenden Berechnungen kann nämlich gezeigt werden, dass der durch diese Vernachlässigungen bedingte Fehler kleiner ist als die durch die Toleranzen der verwendeten Geräte oder die erwähnte Bewegung der Mobilstation erzeugten Fehler.In all of the above considerations, the propagation speed of the electromagnetic waves and in particular the transmission time of the locating frequencies from the control to the mobile station are not taken into account. With corresponding calculations it can be shown that the error caused by these neglections is smaller than the errors generated by the tolerances of the devices used or the mentioned movement of the mobile station.

Im beschriebenen Beispiel liegt der Schnittpunkt 19 des durch die Mobilstation verlaufenden Hyperbelastes 18 mit der Verbindungslinie 12 zwischen dem Schnittpunkt 15 und dem Sender 11. Auf der Verbindungsgeraden gibt es einen weiteren, nicht gezeigten Punkt, der zwischen dem Schnittpunkt 15 und dem Sender 10 liegt und der ebenfalls den Abstand a vom Schnittpunkt 15 aufweist. Wie jedem Fachmann bekannt ist, lässt sich aus der Phasendifferenz der Ortungs- bzw. Messignale bestimmen, ob der Abstand a auf der Verbindungsgeraden 12 zwischen dem Schnittpunkt 15 und dem Sender 10 oder dem Sender 11 liegt, weshalb die Ortsbestimmung eindeutig ist.In the example described, the intersection point 19 of the hyperload 18 running through the mobile station lies with the connecting line 12 between the intersection point 15 and the transmitter 11. On the connecting straight line there is another point, not shown, which lies between the intersection point 15 and the transmitter 10 and which also has the distance a from the intersection 15. As is known to any person skilled in the art, it can be determined from the phase difference of the location or measurement signals whether the distance a lies on the connecting line 12 between the intersection 15 and the transmitter 10 or the transmitter 11, which is why the location is unambiguous.

Die zur Ausführung des neuen Verfahrens erforderliche Anlage kann mit handelsüblichen Bauelementen zusammengestellt werden, weshalb auf deren detaillierte Beschreibung hier ausdrücklich verzichtet wird.The system required to carry out the new process can be put together using commercially available components, which is why its detailed description is expressly omitted here.

Claims (10)

1. Verfahren zum Bestimmen des Ortes eines mobilen Objekts mittels von mindestens zwei ortsfesten Sendestationen ausgesandten funktechnischen Signalen, dadurch gekennzeichnet, dass die Signale direkt oder indirekt ein Feld elektromagnetischer Schwebungen erzeugen, deren phasengleiche Abschnitte mit vorgegebener Geschwindigkeit auf konfokalen Hyperbelästen von der einen zur anderen, je einen Brennpunkt der zugeordneten Hyperbeln bildenden Sendestation wandern und die Zeitdifferenz zwischen dem Durchlauf eines definierten Phasenabschnitts einer Schwebung an einem Bezugsort, dessen Lage relativ zu den beiden Sendestationen durch einen Bezugshyperbelast bestimmt ist, sowie am Ort des mobilen Objekts gemessen und daraus der diesen Ort schneidende Hyperbelast bestimmt wird.1. A method for determining the location of a mobile object by means of radio-technical signals emitted by at least two fixed transmitting stations, characterized in that the signals directly or indirectly generate a field of electromagnetic beats, the in-phase sections of which with predetermined speed on confocal hyper loads from one to the other, each move a focal point of the assigned hyperbola forming transmitter station and measure the time difference between the passage of a defined phase section of a beat at a reference location, the position of which is determined by a reference hyperload relative to the two transmitter stations, and at the location of the mobile object and from this the intersecting location Hyperload is determined. 2. Verfahren nach Anspruch 1, dadurch gekennzeichnet, dass die Wandergeschwindigkeit der phasengleichen Abschnitte der Schwebungen längs der die Hauptachse der Hyperbel bildenden Verbindungsgeraden zwischen den Sendestationen aus der Frequenzendifferenz der funktechnischen Signale errechnet wird und die gemessene Zeitdifferenz und der Abstand zwischen dem Schnittpunkt des Bezugshyperbelasts und dem den Ort des mobilen Objekts schneidenden Hyperbelast mit der Verbindungslinie aus der errechneten Wandergeschwindigkeit und der gemessenen Zeitdifferenz bestimmt wird.2. The method according to claim 1, characterized in that the traveling speed of the in-phase sections of the beatings along the straight line forming the main axis of the hyperbola between the transmitting stations is calculated from the frequency difference of the radio-technical signals and the measured time difference and the distance between the intersection of the reference hyperbolic load and the hyperload intersecting the location of the mobile object with the connecting line from the calculated hiking speed and the measured time difference is true. 3. Verfahren nach Anspruch 1, dadurch gekennzeichnet, dass als definierter Phasenabschnitt der Schwebungen deren Nulldurchgang verwendet wird.3. The method according to claim 1, characterized in that the zero crossing is used as the defined phase section of the beats. 4. Verfahren nach Anspruch 1, dadurch gekennzeichnet, dass mittels drei Sendestationen zwei Felder elektromagnetischer Schwebungen erzeugt werden und für jedes Feld die Zeitdifferenz gemessen und daraus zwei Hyperbeläste bestimmt werden, deren Schnittpunkt dem Ort des mobilen Objekts entspricht.4. The method according to claim 1, characterized in that two fields of electromagnetic beatings are generated by means of three transmitting stations and the time difference is measured for each field and two hyper loads are determined therefrom, whose intersection corresponds to the location of the mobile object. 5. Verfahren nach Anspruch 4, dadurch gekennzeichnet, dass Sendestationen gewählt werden, deren die Hauptachsen der Hyperbeln bildende Verbindungslinien einen stumpfen Winkel einschliessen.5. The method according to claim 4, characterized in that transmission stations are selected, the connecting lines forming the main axes of the hyperbolas form an obtuse angle. 6. Verfahren nach Anspruch 1, dadurch gekennzeichnet, dass die funktechnischen Signale den Trägerwellen von Rundfunksendern aufmoduliert werden.6. The method according to claim 1, characterized in that the radio signals are modulated onto the carrier waves from radio transmitters. 7. Verfahren nach Anspruch 1, dadurch gekennzeichnet, dass die funktechnischen Signale am Bezugsort und am Ort des mobilen Objekts empfangen und vom Bezugsort, gegebenenfalls nach einer vorgängigen Transposition, zu dem mobilen Objekt übertragen und dort die Zeitdifferenz zwischen den Nulldurchgängen der Schwebungen am Bezugsort und am Ort des mobilen Objekts gemessen wird.7. The method according to claim 1, characterized in that the radio signals received at the reference location and at the location of the mobile object and transmitted from the reference location, possibly after a previous transposition, to the mobile object and there the time difference between the zero crossings of the beatings at the reference location and is measured at the location of the mobile object. 8. Verfahren nach Anspruch 1, dadurch gekennzeichnet, dass die funktechnischen Signale am Bezugsort und am Ort des mobilen Objekts empfangen und, gegebenenfalls nach einer vorgängigen Transposition, an eine Leitstelle übertragen und dort die Zeitdifferenz zwischen den Nulldurchgängen der Schwebungen am Bezugsort und am Ort des mobilen Objekts gemessen wird.8. The method according to claim 1, characterized in that the radio signals received at the reference location and at the location of the mobile object and, if necessary after a previous transposition, transmitted to a control center and there the time difference between the zero crossings the beats are measured at the reference location and at the location of the mobile object. 9. Verfahren nach Anspruch 2, dadurch gekennzeichnet, dass am Bezugsort der Nulldurchgang der Schwebung bestimmt und bei jedem Nulldurchgang ein Zeitsignal an das mobile Objekt oder an die Leitstelle übertragen wird.9. The method according to claim 2, characterized in that the zero crossing of the beat is determined at the reference point and a time signal is transmitted to the mobile object or to the control center at each zero crossing. 10. Verfahren nach Anspruch 2, dadurch gekennzeichnet, dass für die Signalübertragung von dem Bezugsort zu dem mobilen Objekt oder zur Leitstelle eine Sendestation im UKW-Bereich verwendet wird.10. The method according to claim 2, characterized in that a transmission station in the FM range is used for the signal transmission from the reference point to the mobile object or to the control center.
EP81200984A 1980-09-10 1981-09-03 Method of determining the position of a mobile object Withdrawn EP0047561A1 (en)

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CH679580 1980-09-10
CH6795/80 1980-09-10

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EP0109215A1 (en) * 1982-10-30 1984-05-23 James Douglas Edwards Craft navigational aid systems
EP0582798A1 (en) * 1992-07-15 1994-02-16 GRUNDIG E.M.V. Elektro-Mechanische Versuchsanstalt Max Grundig GmbH &amp; Co. KG Method and circuit arrangement for determining the geographic position of a broadcast receiver
DE102006059623B3 (en) * 2006-12-14 2008-07-24 Universität Rostock Method and system for position determination

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EP0109215A1 (en) * 1982-10-30 1984-05-23 James Douglas Edwards Craft navigational aid systems
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DE102006059623B3 (en) * 2006-12-14 2008-07-24 Universität Rostock Method and system for position determination

Also Published As

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ES505335A0 (en) 1983-05-16
JPS5779471A (en) 1982-05-18
ES8306261A1 (en) 1983-05-16

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